CN116416085A - Cloud management method, system, server and storage medium of battery exchange station - Google Patents

Abstract

The invention discloses a cloud management method, a system, a server and a storage medium of a power exchange station, wherein the cloud management method is applied to the power exchange station end and specifically comprises the following steps: synchronously uploading real-time power conversion data of a power conversion station to the cloud of the power conversion station; and receiving a detection result generated by the power exchange station cloud based on the real-time power exchange data, wherein the detection result is used for representing whether the real-time power exchange data is abnormal or not. The data of the power exchange station are synchronized to the cloud in real time, and the cloud further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Description

Cloud management method, system, server and storage medium of battery exchange station

Technical Field

The invention belongs to the field of management of a power exchange station, and particularly relates to a cloud management method, a cloud management system, a cloud management server and a cloud management storage medium of the power exchange station.

Background

With more and more points of the power exchange station, when the version of the database of the power exchange equipment is released or problems are encountered, operation and maintenance personnel are required to go to the site to solve the problems and other operations for site investigation, so that the speed is low, and the problems of service influence time, data timeliness and the like are delayed. If site staff operate, operation and maintenance knowledge is needed to be understood, database skills are needed to be understood, and risk of misoperation and deletion of system data is easy to occur. In this context, how to achieve timely and efficient remote management of the power exchange station is a problem that needs to be solved at present.

Disclosure of Invention

The invention aims to overcome the defects of low abnormal speed, delayed service response time, poor timeliness of data and the like in the prior art in the process of checking the station of the power exchange station, and provides a cloud management method, a cloud management system, a cloud management server and a cloud management storage medium of the power exchange station.

The invention solves the technical problems by the following technical scheme:

the cloud management method of the power exchange station is applied to the power exchange station end and specifically comprises the following steps:

synchronously uploading real-time power conversion data of a power conversion station to the cloud of the power conversion station;

And receiving a detection result generated by the power exchange station cloud based on the real-time power exchange data, wherein the detection result is used for representing whether the real-time power exchange data is abnormal or not.

In the scheme, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Preferably, the uploading the real-time power conversion data of the power conversion station to the power conversion station cloud end includes:

and synchronously uploading real-time power conversion data of the power conversion station to the cloud of the power conversion station based on a preset VPN network.

In the scheme, real-time data synchronization is realized based on a preset VPN network, and the high efficiency and the safety of data transmission are ensured.

Preferably, the cloud management method further comprises:

and generating a backup data set by using the local power conversion data of the power conversion station and the detection result, and sending the backup data set to the cloud of the power conversion station for storage.

In the scheme, local power conversion data and detection results of the power conversion station are backed up and stored in the cloud for subsequent relevant data analysis and research and development based on big data.

Preferably, the cloud management method further comprises:

presetting a first backup period corresponding to a power exchange station;

the step of generating a backup data set by using the local power conversion data of the power conversion station and the detection result and sending the backup data set to the cloud of the power conversion station for storage specifically comprises the following steps:

and generating a backup data set based on the local power conversion data of the power conversion station and the detection result and sending the backup data set to the cloud of the power conversion station for storage.

In the scheme, the backup period corresponding to the power exchange station is set, so that statistical analysis of backup data is facilitated, wherein different backup periods can be set for different power exchange stations, the backup rate is improved, and meanwhile, network congestion during data backup can be relieved.

Preferably, the cloud management method further comprises:

and receiving an alarm notification generated by the power exchange station cloud based on the abnormal detection result.

In the scheme, once the cloud of the power exchange station detects abnormal power exchange, alarm notification can be timely generated through cloud monitoring and returned to the power exchange station end, so that on-site maintenance personnel can quickly react and process problems, and the fault processing time is shortened.

Preferably, the cloud management method further comprises:

determining an abnormal target object and abnormal matters of the power exchange station according to the detection result;

the target object comprises at least one of a target battery, a target battery exchange process and/or target battery exchange equipment, and the abnormal event comprises at least one of a battery exchange program abnormality, a battery exchange fault, a battery exchange equipment fault, a charging equipment fault and a battery taking-out fault.

According to the technical scheme, the abnormal target object and abnormal matters of the power exchange station are further determined according to the detection result returned by the cloud of the power exchange station, such as abnormal power exchange program, power exchange battery fault, power exchange equipment fault, charging equipment fault, battery taking-out fault and the like, so that field maintenance personnel can quickly and effectively know specific abnormal conditions, the problems can be processed in time, and the fault processing time is shortened.

The cloud management method of the power exchange station is applied to the cloud of the power exchange station and specifically comprises the following steps:

receiving real-time power exchange data of a power exchange station synchronously uploaded by a power exchange station end;

and generating a detection result based on the real-time power conversion data and sending the detection result to the power conversion station end, wherein the detection result is used for representing whether the real-time power conversion data is abnormal or not.

In the scheme, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Preferably, the receiving the real-time power exchange data of the power exchange station uploaded by the power exchange station end specifically includes:

and receiving real-time power exchange data of the power exchange station, which are uploaded by the power exchange station terminal based on a preset VPN network.

In the scheme, real-time data synchronization is realized based on a preset VPN network, and the high efficiency and the safety of data transmission are ensured.

Preferably, the cloud management method further comprises:

and receiving a backup data set which is sent by the power exchange station terminal and is generated based on the local power exchange data of the power exchange station and the detection result.

In the scheme, local power conversion data and detection results of the power conversion station are backed up and stored in the cloud for subsequent relevant data analysis and research and development based on big data.

Preferably, the cloud management method further comprises:

presetting a second backup period corresponding to the power exchange station;

the receiving the backup data set generated based on the local power conversion data of the power conversion station and the detection result and sent by the power conversion station end specifically comprises the following steps:

and receiving a backup data set which is sent by the power exchange station terminal based on the second backup period and is generated based on the local power exchange data of the power exchange station and the detection result.

In the scheme, the backup period corresponding to the power exchange station is set, so that statistical analysis of backup data is facilitated, wherein different backup periods can be set for different power exchange stations, the backup rate is improved, and meanwhile, network congestion during data backup can be relieved.

Preferably, the cloud management method further comprises:

and generating an alarm notice based on the abnormal detection result and sending the alarm notice to the power exchange station.

In the scheme, once the cloud of the power exchange station detects abnormal power exchange, alarm notification can be timely generated through cloud monitoring and returned to the power exchange station end, so that on-site maintenance personnel can quickly react and process problems, and the fault processing time is shortened.

Preferably, the cloud management method further comprises:

Determining an abnormal target object and abnormal matters of the power exchange station according to the detection result;

the target object comprises at least one of a target battery, a target battery exchange process and/or target battery exchange equipment, and the abnormal event comprises at least one of a battery exchange program abnormality, a battery exchange fault, a battery exchange equipment fault, a charging equipment fault and a battery taking-out fault.

In the scheme, the abnormal target object and abnormal matters of the power exchange station are further determined according to the detection result, such as abnormal power exchange program, power exchange battery fault, power exchange equipment fault, charging equipment fault, battery taking-out fault and the like, so that field maintenance personnel can quickly and effectively know specific abnormal conditions, the problem can be processed in time, and the fault processing time is shortened.

The cloud management system of the power exchange station is applied to a power exchange station end and specifically comprises the following components:

the synchronization module is used for synchronously uploading real-time power conversion data of the power conversion station to the cloud of the power conversion station;

the abnormal information receiving module is used for receiving a detection result generated by the power exchange station cloud based on the real-time power exchange data, and the detection result is used for representing whether the real-time power exchange data is abnormal or not.

In the scheme, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Preferably, the synchronization module is specifically configured to synchronously upload real-time power conversion data of the power conversion station to the cloud of the power conversion station based on a preset VPN network.

In the scheme, real-time data synchronization is realized based on a preset VPN network, and the high efficiency and the safety of data transmission are ensured.

Preferably, the cloud management system further comprises:

and the backup module is used for generating a backup data set from the local power conversion data of the power conversion station and the detection result and sending the backup data set to the cloud of the power conversion station for storage.

In the scheme, local power conversion data and detection results of the power conversion station are backed up and stored in the cloud for subsequent relevant data analysis and research and development based on big data.

Preferably, the cloud management system further comprises:

the first period presetting module is used for presetting a first backup period corresponding to the power exchange station;

the backup module is specifically configured to generate a backup data set based on the local power conversion data of the power conversion station and the detection result and send the backup data set to the cloud of the power conversion station for storage.

In the scheme, the backup period corresponding to the power exchange station is set, so that statistical analysis of backup data is facilitated, wherein different backup periods can be set for different power exchange stations, the backup rate is improved, and meanwhile, network congestion during data backup can be relieved.

Preferably, the cloud management system further comprises:

and the alarm receiving module is used for receiving alarm notification generated by the cloud of the battery exchange station based on the abnormal detection result.

In the scheme, once the cloud of the power exchange station detects abnormal power exchange, alarm notification can be timely generated through cloud monitoring and returned to the power exchange station end, so that on-site maintenance personnel can quickly react and process problems, and the fault processing time is shortened.

Preferably, the cloud management system further comprises:

the first abnormality determining module is used for determining an abnormal target object and abnormal matters of the power exchange station according to the detection result;

The target object comprises at least one of a target battery, a target battery exchange process and/or target battery exchange equipment, and the abnormal event comprises at least one of a battery exchange program abnormality, a battery exchange fault, a battery exchange equipment fault, a charging equipment fault and a battery taking-out fault.

According to the technical scheme, the abnormal target object and abnormal matters of the power exchange station are further determined according to the detection result returned by the cloud of the power exchange station, such as abnormal power exchange program, power exchange battery fault, power exchange equipment fault, charging equipment fault, battery taking-out fault and the like, so that field maintenance personnel can quickly and effectively know specific abnormal conditions, the problems can be processed in time, and the fault processing time is shortened.

A cloud management system of a power exchange station is applied to a cloud of the power exchange station, and specifically comprises the following components:

the synchronous data receiving module is used for receiving real-time power exchanging data of the power exchanging station, which is synchronously uploaded by the power exchanging station end;

the abnormal information detection module is used for generating a detection result based on the real-time power conversion data and sending the detection result to the power conversion station end, and the detection result is used for representing whether the real-time power conversion data is abnormal or not.

In the scheme, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Preferably, the synchronous data receiving module is specifically configured to receive real-time power conversion data of the power conversion station uploaded by the power conversion station terminal based on a preset VPN network.

In the scheme, real-time data synchronization is realized based on a preset VPN network, and the high efficiency and the safety of data transmission are ensured.

Preferably, the cloud management system further comprises:

and the backup data receiving module is used for receiving the backup data set generated based on the local power conversion data of the power conversion station and the detection result and sent by the power conversion station end.

In the scheme, local power conversion data and detection results of the power conversion station are backed up and stored in the cloud for subsequent relevant data analysis and research and development based on big data.

Preferably, the cloud management system further comprises:

the second period presetting module is used for presetting a second backup period corresponding to the power exchange station;

the backup data receiving module is specifically configured to receive a backup data set generated based on the local power conversion data of the power conversion station and the detection result and sent by the power conversion station end based on the second backup period.

In the scheme, the backup period corresponding to the power exchange station is set, so that statistical analysis of backup data is facilitated, wherein different backup periods can be set for different power exchange stations, the backup rate is improved, and meanwhile, network congestion during data backup can be relieved.

Preferably, the cloud management system further comprises:

and the alarm module is used for generating an alarm notification based on an abnormal detection result and sending the alarm notification to the station end of the power exchange station.

In the scheme, once the cloud of the power exchange station detects abnormal power exchange, alarm notification can be timely generated through cloud monitoring and returned to the power exchange station end, so that on-site maintenance personnel can quickly react and process problems, and the fault processing time is shortened.

Preferably, the cloud management system further comprises:

the second abnormality determining module is used for determining an abnormal target object and abnormal matters of the power exchange station according to the detection result;

The target object comprises at least one of a target battery, a target battery exchange process and/or target battery exchange equipment, and the abnormal event comprises at least one of a battery exchange program abnormality, a battery exchange fault, a battery exchange equipment fault, a charging equipment fault and a battery taking-out fault.

According to the technical scheme, the abnormal target object and abnormal matters of the power exchange station are further determined according to the detection result returned by the cloud of the power exchange station, such as abnormal power exchange program, power exchange battery fault, power exchange equipment fault, charging equipment fault, battery taking-out fault and the like, so that field maintenance personnel can quickly and effectively know specific abnormal conditions, the problems can be processed in time, and the fault processing time is shortened.

A server comprising a memory, a processor and a computer program stored on the memory and executable on the processor, the processor implementing the cloud management method of a power exchange station as described above when executing the computer program.

A computer readable storage medium having stored thereon a computer program which when executed by a processor implements the cloud management method of a power exchange station described above.

The invention has the positive progress effects that: in the method, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Drawings

Fig. 1 is a flowchart of a cloud management method of a power exchange station applied to a power exchange station end in embodiment 1 of the present invention.

Fig. 2 is a flowchart of a preferred implementation of the cloud management method of the power exchange station applied to the power exchange station end in embodiment 1 of the present invention.

Fig. 3 is a flowchart of a cloud management method of a power exchange station applied to the cloud of the power exchange station in embodiment 2 of the present invention.

Fig. 4 is a flowchart of a preferred implementation of a cloud management method of a power exchange station applied to the cloud of the power exchange station according to embodiment 2 of the present invention.

Fig. 5 is a schematic block diagram of a cloud management system of a power exchange station applied to a power exchange station end in embodiment 3 of the present invention.

Fig. 6 is a schematic block diagram of a preferred implementation of the cloud management system of the power exchange station applied to the power exchange station end in embodiment 3 of the present invention.

Fig. 7 is a schematic block diagram of a cloud management system of a power exchange station applied to a power exchange station cloud in embodiment 4 of the present invention.

Fig. 8 is a schematic block diagram of a preferred implementation of the cloud management system of the power exchange station applied to the cloud of the power exchange station in embodiment 4 of the present invention.

Fig. 9 is a schematic structural diagram of an electronic device according to embodiment 5 of the present invention.

Detailed Description

The invention is further illustrated by means of the following examples, which are not intended to limit the scope of the invention.

Example 1

The cloud management method of the power exchange station is applied to the power exchange station end, and can be realized by adopting station end electronic equipment and/or a station server of the power exchange station, wherein the station end electronic equipment can be but is not limited to a mobile terminal, a computer, an embedded chip of the in-station charging and power exchange equipment and the like, and the station server of the power exchange station can be but is not limited to a server or a server cluster and the like, as shown in fig. 1, and specifically comprises the following steps:

step 11, synchronously uploading real-time power conversion data of the power conversion station to the cloud of the power conversion station;

the real-time power exchange data of the power exchange station is data related to power exchange, which is acquired in the power exchange station, and includes but is not limited to: battery replacement data, charging data, battery replacement user data, operational status data, and the like. After responding to the access message of the cloud end of the power exchange station, carrying out real-time synchronization on the data, and specifically, initiating an access request by the power exchange station; then receiving an access message generated by the cloud of the power exchange station in response to the access request; and then, the deployment of the site server of the power exchange station is realized based on the access message, and a management account corresponding to the site server is generated for subsequent login connection use.

And step 12, receiving a detection result generated by the power conversion station cloud based on the real-time power conversion data, wherein the detection result is used for representing whether the real-time power conversion data is abnormal or not.

The power plant data may be manipulated, managed, backed up, monitored, etc., by an integration tool, such as an integration of archery, sor, zabbix, xtrabackup, analog, etc. The research and development or service personnel receive the alarm, and can also check whether the application problem, the battery problem or the abnormality occurs in the power conversion process through a local tool, so that the power conversion efficiency is improved by timely processing.

In the implementation manner, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

In this embodiment, a preferred implementation manner of a cloud management method of a power exchange station is provided, as shown in fig. 2, step 11 specifically includes:

and step 111, synchronously uploading real-time power conversion data of the power conversion station to the cloud of the power conversion station based on a preset VPN network.

The real-time data synchronization is realized based on a preset VPN network, and the high efficiency and the safety of data transmission are ensured.

Referring to fig. 2, after step 12, the cloud management method further includes:

and 13, generating a backup data set by using the local power conversion data of the power conversion station and the detection result, and sending the backup data set to the cloud of the power conversion station for storage.

And the backup data set is generated by realizing data backup based on shell script and an allowable at the terminal of the power exchange station, and is uploaded to the cloud of the power exchange station. And backing up the local power conversion data and the detection result of the power conversion station and storing the local power conversion data and the detection result in the cloud for subsequent relevant data analysis and research and development based on big data. In addition, after a first backup request initiated by the cloud end of the power exchange station is responded, the local power exchange data and the detection result of the power exchange station are generated into a backup data set and sent to the cloud end of the power exchange station for storage; or, based on the second backup request generated by the power exchange station, generating a backup data set by the local power exchange data and the detection result of the power exchange station, and sending the backup data set to the cloud of the power exchange station for storage.

Referring to fig. 2, before step 13, the cloud management method further includes:

step 121, presetting a first backup period corresponding to the power exchange station;

further, step 13 specifically includes:

and generating a backup data set based on the local power conversion data of the power conversion station and the detection result in the first backup period, and sending the backup data set to the cloud of the power conversion station for storage.

In the implementation manner, the backup period corresponding to the power exchange station is set, so that statistical analysis of backup data is facilitated, wherein different backup periods can be set for different power exchange stations, the backup rate is improved, and meanwhile, network congestion during data backup can be relieved.

Referring to fig. 2, after step 13, the cloud management method further includes:

and 14, receiving an alarm notification generated by the cloud of the power exchange station based on an abnormal detection result.

Once the cloud end of the power exchange station detects abnormal power exchange, an alarm notification can be timely generated through cloud end monitoring and returned to the power exchange station end, so that on-site maintenance personnel can quickly react and process problems, and the fault processing time is shortened.

Step 15, determining an abnormal target object and abnormal matters of the power exchange station according to the detection result;

the target object comprises at least one of a target battery replacement, a target battery replacement process and/or target battery replacement equipment, and the abnormal event comprises at least one of abnormal battery replacement process, battery replacement failure, battery replacement equipment failure, charging equipment failure and battery taking-out failure.

After notifying the power exchange station staff to repair the abnormal target object and the abnormal event, the abnormal target object and the abnormal event can be repaired and modified into a normal detection result, and the detection result is synchronously uploaded to the cloud server.

In the implementation manner, the abnormal target object and abnormal matters of the power exchange station are further determined according to the detection result returned by the cloud of the power exchange station, such as abnormal power exchange program, power exchange battery fault, power exchange equipment fault, charging equipment fault, battery taking-out fault and the like, so that field maintenance personnel can quickly and effectively know specific abnormal conditions, the problems can be processed in time, and the fault processing time is shortened.

In this embodiment, the data of the power exchange station is synchronized to the cloud in real time, and the cloud further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Example 2

The cloud management method of the power exchange station is applied to the cloud of the power exchange station, and can be realized by adopting cloud electronic equipment and/or a cloud server, wherein the cloud electronic equipment can be a mobile terminal, a computer and the like, the cloud server can be a server or a server cluster and the like, and the cloud management method specifically comprises the following steps:

Step 21, receiving real-time power conversion data of a power conversion station, which are synchronously uploaded by a power conversion station end;

the real-time power exchange data of the power exchange station is data related to power exchange, which is acquired in the power exchange station, and includes but is not limited to: battery replacement data, charging data, battery replacement user data, operational status data, and the like. And generating a corresponding access message by responding to an access request initiated by the power exchange station and sending the access message to the power exchange station, wherein the access request is used for representing that the power exchange station is successfully accessed into the cloud of the power exchange station. Meanwhile, the station end of the power exchange station generates a management account corresponding to the station server based on the access message for subsequent login connection use.

And 22, generating a detection result based on the real-time power conversion data and sending the detection result to a power conversion station end, wherein the detection result is used for representing whether the real-time power conversion data is abnormal or not.

The power plant data may be manipulated, managed, backed up, monitored, etc., by an integration tool, such as an integration of archery, sor, zabbix, xtrabackup, analog, etc. The research and development or service personnel receive the alarm, and can also check whether the application problem, the battery problem or the abnormality occurs in the power conversion process through a local tool, so that the power conversion efficiency is improved by timely processing.

In the implementation manner, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

In this embodiment, a preferred implementation manner of the cloud management method of the power exchange station is provided, as shown in fig. 4, step 21 specifically includes:

step 211, receiving real-time power conversion data of the power conversion station uploaded by the power conversion station terminal based on a preset VPN network.

The real-time data synchronization is realized based on a preset VPN network, and the high efficiency and the safety of data transmission are ensured.

Referring to fig. 4, after step 22, the cloud management method further includes:

and step 23, receiving a backup data set generated based on local power conversion data and detection results of the power conversion station and transmitted by the power conversion station side.

And the backup data set is generated by realizing data backup based on shell script and an allowable at the terminal of the power exchange station, and is uploaded to the cloud of the power exchange station. And backing up the local power conversion data and the detection result of the power conversion station and storing the local power conversion data and the detection result in the cloud for subsequent relevant data analysis and research and development based on big data. In addition, after a first backup request initiated by the cloud end of the power exchange station is responded, the local power exchange data and the detection result of the power exchange station are generated into a backup data set and sent to the cloud end of the power exchange station for storage; or, based on the second backup request generated by the power exchange station, generating a backup data set by the local power exchange data and the detection result of the power exchange station, and sending the backup data set to the cloud of the power exchange station for storage.

Referring to fig. 4, before step 23, the cloud management method further includes:

step 221, presetting a second backup period corresponding to the power exchange station;

further, step 23 specifically includes:

and receiving a backup data set generated by the power exchange station terminal based on the local power exchange data of the power exchange station and the detection result and transmitted by the second backup period.

In the implementation manner, the backup period corresponding to the power exchange station is set, so that statistical analysis of backup data is facilitated, wherein different backup periods can be set for different power exchange stations, the backup rate is improved, and meanwhile, network congestion during data backup can be relieved.

Referring to fig. 4, after step 13, the cloud management method further includes:

and step 24, generating an alarm notification based on the abnormal detection result and sending the alarm notification to the station end of the power exchange station.

Once the cloud end of the power exchange station detects abnormal power exchange, an alarm notification can be timely generated through cloud end monitoring and returned to the power exchange station end, so that on-site maintenance personnel can quickly react and process problems, and the fault processing time is shortened.

Step 25, determining an abnormal target object and abnormal matters of the power exchange station according to the detection result;

the target object comprises at least one of a target battery replacement, a target battery replacement process and/or target battery replacement equipment, and the abnormal event comprises at least one of abnormal battery replacement process, battery replacement failure, battery replacement equipment failure, charging equipment failure and battery taking-out failure.

After notifying the power exchange station staff to repair the abnormal target object and the abnormal event, the abnormal target object and the abnormal event can be repaired and then modified into a normal detection result, and the detection result is synchronized to the cloud server.

In the implementation manner, the abnormal target object and abnormal matters of the power exchange station are further determined according to the detection result of the cloud of the power exchange station, such as abnormal power exchange program, power exchange battery fault, power exchange equipment fault, charging equipment fault, battery taking-out fault and the like, so that field maintenance personnel can quickly and effectively know specific abnormal conditions, the problems can be processed in time, and the fault processing time is shortened.

In this embodiment, the data of the power exchange station is synchronized to the cloud in real time, and the cloud further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Example 3

The cloud management system of the power exchange station is applied to a power exchange station end, can be realized based on station end electronic equipment and/or a station server of the power exchange station, the station end electronic equipment can be but not limited to a mobile terminal, a computer, an embedded chip of the in-station charging and power exchange equipment and the like, and the station server of the power exchange station can be but not limited to a server or a server cluster and the like, as shown in fig. 5, and specifically comprises:

The synchronization module 31 is configured to synchronously upload real-time power conversion data of the power conversion station to the cloud of the power conversion station;

the real-time power exchange data of the power exchange station is data related to power exchange, which is acquired in the power exchange station, and includes but is not limited to: battery replacement data, charging data, battery replacement user data, operational status data, and the like. After responding to the access message of the cloud end of the power exchange station, carrying out real-time synchronization on the data, and specifically, initiating an access request by the power exchange station; then receiving an access message generated by the cloud of the power exchange station in response to the access request; and then, the deployment of the site server of the power exchange station is realized based on the access message, and a management account corresponding to the site server is generated for subsequent login connection use.

The abnormal information receiving module 32 is configured to receive a detection result generated by the cloud of the power conversion station based on the real-time power conversion data, where the detection result is used to characterize whether the real-time power conversion data is abnormal.

The power plant data may be manipulated, managed, backed up, monitored, etc., by an integration tool, such as an integration of archery, sor, zabbix, xtrabackup, analog, etc. The research and development or service personnel receive the alarm, and can also check whether the application problem, the battery problem or the abnormality occurs in the power conversion process through a local tool, so that the power conversion efficiency is improved by timely processing.

In the implementation manner, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

In this embodiment, a preferred implementation manner of the cloud management system of the power exchange station is provided, and the synchronization module 31 is specifically configured to synchronously upload real-time power exchange data of the power exchange station to the cloud of the power exchange station based on a preset VPN network.

The real-time data synchronization is realized based on a preset VPN network, and the high efficiency and the safety of data transmission are ensured.

As shown in fig. 6, the cloud management system further includes:

the backup module 33 is configured to generate a backup data set from the local power conversion data and the detection result of the power conversion station, and send the backup data set to the cloud of the power conversion station for storage.

And the backup data set is generated by realizing data backup based on shell script and an allowable at the terminal of the power exchange station, and is uploaded to the cloud of the power exchange station. And backing up the local power conversion data and the detection result of the power conversion station and storing the local power conversion data and the detection result in the cloud for subsequent relevant data analysis and research and development based on big data. In addition, after a first backup request initiated by the cloud end of the power exchange station is responded, the local power exchange data and the detection result of the power exchange station are generated into a backup data set and sent to the cloud end of the power exchange station for storage; or, based on the second backup request generated by the power exchange station, generating a backup data set by the local power exchange data and the detection result of the power exchange station, and sending the backup data set to the cloud of the power exchange station for storage.

A first period presetting module 34, configured to preset a first backup period corresponding to the power exchange station;

the backup module 33 is specifically configured to generate a backup data set based on the local power conversion data of the power conversion station and the detection result and send the backup data set to the cloud of the power conversion station for storage.

The backup period corresponding to the power exchange station is set, so that statistical analysis of backup data is facilitated, different backup periods can be set for different power exchange stations, the backup rate is improved, and network congestion during data backup can be relieved.

And the alarm receiving module 35 is used for receiving alarm notification generated by the cloud of the battery exchange station based on the abnormal detection result.

Once the cloud end of the power exchange station detects abnormal power exchange, an alarm notification can be timely generated through cloud end monitoring and returned to the power exchange station end, so that on-site maintenance personnel can quickly react and process problems, and the fault processing time is shortened.

A first abnormality determination module 36, configured to determine, according to the detection result, a target object and an abnormal item of the power exchange station that are abnormal;

the target object comprises at least one of a target battery replacement, a target battery replacement process and/or target battery replacement equipment, and the abnormal event comprises at least one of abnormal battery replacement process, battery replacement failure, battery replacement equipment failure, charging equipment failure and battery taking-out failure.

After notifying the power exchange station staff to repair the abnormal target object and the abnormal event, the abnormal target object and the abnormal event can be repaired and modified into a normal detection result, and the detection result is synchronously uploaded to the cloud server.

In the implementation manner, the abnormal target object and abnormal matters of the power exchange station are further determined according to the detection result returned by the cloud of the power exchange station, such as abnormal power exchange program, power exchange battery fault, power exchange equipment fault, charging equipment fault, battery taking-out fault and the like, so that field maintenance personnel can quickly and effectively know specific abnormal conditions, the problems can be processed in time, and the fault processing time is shortened.

In this embodiment, the data of the power exchange station is synchronized to the cloud in real time, and the cloud further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Example 4

The cloud management system of the power exchange station is applied to a cloud of the power exchange station, and can be realized based on cloud electronic equipment and/or a cloud server, wherein the cloud electronic equipment can be a mobile terminal, a computer and the like, the cloud server can be a server or a server cluster and the like, as shown in fig. 7, and the cloud management system specifically comprises:

The synchronous data receiving module 41 is used for receiving real-time power exchanging data of the power exchanging station, which is synchronously uploaded by the power exchanging station end;

the real-time power exchange data of the power exchange station is data related to power exchange, which is acquired in the power exchange station, and includes but is not limited to: battery replacement data, charging data, battery replacement user data, operational status data, and the like. And generating a corresponding access message by responding to an access request initiated by the power exchange station and sending the access message to the power exchange station, wherein the access request is used for representing that the power exchange station is successfully accessed into the cloud of the power exchange station. Meanwhile, the station end of the power exchange station generates a management account corresponding to the station server based on the access message for subsequent login connection use.

The abnormal information detection module 42 is configured to generate a detection result based on the real-time power conversion data and send the detection result to the power conversion station end, where the detection result is used to characterize whether the real-time power conversion data is abnormal.

The power plant data may be manipulated, managed, backed up, monitored, etc., by an integration tool, such as an integration of archery, sor, zabbix, xtrabackup, analog, etc. The research and development or service personnel receive the alarm, and can also check whether the application problem, the battery problem or the abnormality occurs in the power conversion process through a local tool, so that the power conversion efficiency is improved by timely processing.

In the implementation manner, the data of the power exchange station are synchronized to the cloud end in real time, and the cloud end further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

In this embodiment, a preferred implementation manner of the cloud management system of the power exchange station is provided, and the synchronous data receiving module 41 is specifically configured to receive real-time power exchange data of the power exchange station uploaded by the power exchange station terminal based on a preset VPN network.

The real-time data synchronization is realized based on a preset VPN network, and the high efficiency and the safety of data transmission are ensured.

As shown in fig. 8, the cloud management system further includes:

and the backup data receiving module 43 is configured to receive the backup data set generated based on the local power exchange data and the detection result of the power exchange station and sent by the power exchange station end.

And the backup data set is generated by realizing data backup based on shell script and an allowable at the terminal of the power exchange station, and is uploaded to the cloud of the power exchange station. And backing up the local power conversion data and the detection result of the power conversion station and storing the local power conversion data and the detection result in the cloud for subsequent relevant data analysis and research and development based on big data. In addition, after a first backup request initiated by the cloud end of the power exchange station is responded, the local power exchange data and the detection result of the power exchange station are generated into a backup data set and sent to the cloud end of the power exchange station for storage; or, based on the second backup request generated by the power exchange station, generating a backup data set by the local power exchange data and the detection result of the power exchange station, and sending the backup data set to the cloud of the power exchange station for storage.

A second period presetting module 44, configured to preset a second backup period corresponding to the power exchange station;

the backup data receiving module 43 is specifically configured to receive a backup data set generated based on the local power conversion data of the power conversion station and the detection result and sent by the power conversion station end based on the second backup period.

The backup period corresponding to the power exchange station is set, so that statistical analysis of backup data is facilitated, different backup periods can be set for different power exchange stations, the backup rate is improved, and network congestion during data backup can be relieved.

And the alarm module 45 is used for generating an alarm notification based on the abnormal detection result and sending the alarm notification to the station end of the power exchange station.

Once the cloud end of the power exchange station detects abnormal power exchange, an alarm notification can be timely generated through cloud end monitoring and returned to the power exchange station end, so that on-site maintenance personnel can quickly react and process problems, and the fault processing time is shortened.

A second abnormality determination module 46, configured to determine, according to the detection result, a target object and an abnormal item of the power exchange station that are abnormal;

the target object comprises at least one of a target battery replacement, a target battery replacement process and/or target battery replacement equipment, and the abnormal event comprises at least one of abnormal battery replacement process, battery replacement failure, battery replacement equipment failure, charging equipment failure and battery taking-out failure.

After notifying the power exchange station staff to repair the abnormal target object and the abnormal event, the abnormal target object and the abnormal event can be repaired and then modified into a normal detection result, and the detection result is synchronized to the cloud server.

According to the detection result of the cloud of the power exchange station, abnormal target objects and abnormal matters of the power exchange station are further determined, such as abnormal power exchange program, power exchange battery faults, power exchange equipment faults, charging equipment faults, battery taking-out faults and the like, specific abnormal conditions can be known by field maintenance personnel rapidly and effectively, so that problems can be processed in time, and fault processing time is shortened.

In this embodiment, the data of the power exchange station is synchronized to the cloud in real time, and the cloud further detects and feeds back the data in real time. The timeliness of the cloud database is ensured synchronously in real time by data, once the power change abnormality occurs, the power change abnormality can be timely alarmed through cloud monitoring, maintenance personnel can also conveniently respond to the processing problem quickly, the fault processing time is shortened, the time cost of processing the problem manually to a site is reduced through cloud unified management, and subsequent relevant research and development based on big data are also facilitated.

Example 5

A server comprising a memory, a processor and a computer program stored on the memory and executable on the processor, the processor implementing the cloud management method of a power exchange station of embodiment 1 or 2 when executing the computer program.

Fig. 9 is a schematic structural diagram of a server according to the present embodiment. Fig. 9 illustrates a block diagram of an exemplary server 90 suitable for use in implementing embodiments of the present invention. The server 90 shown in fig. 9 is merely an example, and should not be construed as limiting the functionality and scope of use of the embodiments of the present invention.

As shown in fig. 9, the server 90 may be embodied in the form of a general purpose computing device, which may be a server device, for example. The components of server 90 may include, but are not limited to: at least one processor 91, at least one memory 92, a bus 93 connecting the different system components, including the memory 92 and the processor 91.

The bus 93 includes a data bus, an address bus, and a control bus.

The memory 92 may include volatile memory such as Random Access Memory (RAM) 921 and/or cache memory 922, and may further include Read Only Memory (ROM) 923.

Memory 92 may also include a program tool 925 having a set (at least one) of program modules 924, such program modules 924 including, but not limited to: an operating system, one or more application programs, other program modules, and program data, each or some combination of which may include an implementation of a network environment.

The processor 91 executes various functional applications and data processing by running a computer program stored in the memory 92.

The server 90 may also communicate with one or more external devices 94 (e.g., keyboard, pointing device, etc.). Such communication may occur through an input/output (I/O) interface 95. Also, the server 90 may communicate with one or more networks such as a Local Area Network (LAN), a Wide Area Network (WAN) and/or a public network, such as the Internet, via a network adapter 96. The network adapter 96 communicates with other modules of the server 90 via bus 93. It should be appreciated that although not shown, other hardware and/or software modules may be used in connection with server 90, including, but not limited to: microcode, device drivers, redundant processors, external disk drive arrays, RAID (disk array) systems, tape drives, data backup storage systems, and the like.

It should be noted that although several units/modules or sub-units/modules of a server are mentioned in the above detailed description, this division is only exemplary and not mandatory. Indeed, the features and functionality of two or more units/modules described above may be embodied in one unit/module according to embodiments of the present application. Conversely, the features and functions of one unit/module described above may be further divided into ones that are embodied by a plurality of units/modules.

Example 6

A computer-readable storage medium, on which a computer program is stored, which when being executed by a processor, implements the cloud management method of a power exchange station according to embodiment 1 or 2.

More specifically, among others, readable storage media may be employed including, but not limited to: portable disk, hard disk, random access memory, read only memory, erasable programmable read only memory, optical storage device, magnetic storage device, or any suitable combination of the foregoing.

In a possible embodiment, the invention may also be implemented in the form of a program product comprising program code for causing a terminal device to carry out the cloud management method of implementing the power exchange station according to embodiment 1 or 2, when said program product is run on the terminal device.

Wherein the program code for carrying out the invention may be written in any combination of one or more programming languages, which program code may execute entirely on the user device, partly on the user device, as a stand-alone software package, partly on the user device and partly on the remote device or entirely on the remote device.

While specific embodiments of the invention have been described above, it will be appreciated by those skilled in the art that this is by way of example only, and the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the principles and spirit of the invention, but such changes and modifications fall within the scope of the invention.

Claims (15)

1. The cloud management method of the power exchange station is characterized by being applied to the power exchange station side and specifically comprising the following steps:

synchronously uploading real-time power conversion data of a power conversion station to the cloud of the power conversion station;

and receiving a detection result generated by the power exchange station cloud based on the real-time power exchange data, wherein the detection result is used for representing whether the real-time power exchange data is abnormal or not.

2. The cloud management method of a power exchange station according to claim 1, wherein the uploading the real-time power exchange data of the power exchange station to the cloud of the power exchange station synchronously comprises:

and synchronously uploading real-time power conversion data of the power conversion station to the cloud of the power conversion station based on a preset VPN network.

3. The method of cloud management of a power exchange station of claim 1, further comprising:

And generating a backup data set by using the local power conversion data of the power conversion station and the detection result, and sending the backup data set to the cloud of the power conversion station for storage.

4. A method of cloud management of a power exchange station as claimed in claim 3, further comprising:

presetting a first backup period corresponding to a power exchange station;

the step of generating a backup data set by using the local power conversion data of the power conversion station and the detection result and sending the backup data set to the cloud of the power conversion station for storage specifically comprises the following steps:

and generating a backup data set based on the local power conversion data of the power conversion station and the detection result and sending the backup data set to the cloud of the power conversion station for storage.

5. The method of cloud management of a power exchange station of claim 1, further comprising:

and receiving an alarm notification generated by the power exchange station cloud based on the abnormal detection result.

6. The method of cloud management of a power exchange station of claim 1, further comprising:

determining an abnormal target object and abnormal matters of the power exchange station according to the detection result;

the target object comprises at least one of a target battery, a target battery exchange process and/or target battery exchange equipment, and the abnormal event comprises at least one of a battery exchange program abnormality, a battery exchange fault, a battery exchange equipment fault, a charging equipment fault and a battery taking-out fault.

7. The cloud management method for the power exchange station is characterized by being applied to the cloud of the power exchange station and specifically comprising the following steps of:

receiving real-time power exchange data of a power exchange station synchronously uploaded by a power exchange station end;

and generating a detection result based on the real-time power conversion data and sending the detection result to the power conversion station end, wherein the detection result is used for representing whether the real-time power conversion data is abnormal or not.

8. The cloud management method of the power exchange station as set forth in claim 7, wherein the receiving the real-time power exchange data of the power exchange station uploaded by the power exchange station end specifically includes:

and receiving real-time power exchange data of the power exchange station, which are uploaded by the power exchange station terminal based on a preset VPN network.

9. The method of cloud management for a power exchange station of claim 7, said method further comprising:

and receiving a backup data set which is sent by the power exchange station terminal and is generated based on the local power exchange data of the power exchange station and the detection result.

10. The method of cloud management for a power exchange station of claim 9, further comprising:

presetting a second backup period corresponding to the power exchange station;

the receiving the backup data set generated based on the local power conversion data of the power conversion station and the detection result and sent by the power conversion station end specifically comprises the following steps:

And receiving a backup data set which is sent by the power exchange station terminal based on the second backup period and is generated based on the local power exchange data of the power exchange station and the detection result.

11. The method of cloud management for a power exchange station of claim 7, said method further comprising:

and generating an alarm notice based on the abnormal detection result and sending the alarm notice to the power exchange station.

12. The method of cloud management for a power exchange station of claim 7, said method further comprising:

determining an abnormal target object and abnormal matters of the power exchange station according to the detection result;

the target object comprises at least one of a target battery, a target battery exchange process and/or target battery exchange equipment, and the abnormal event comprises at least one of a battery exchange program abnormality, a battery exchange fault, a battery exchange equipment fault, a charging equipment fault and a battery taking-out fault.

13. The cloud management system of the power exchange station is characterized by being applied to the power exchange station side and specifically comprising the following steps:

the synchronization module is used for synchronously uploading real-time power conversion data of the power conversion station to the cloud of the power conversion station;

The abnormal information receiving module is used for receiving a detection result generated by the power exchange station cloud based on the real-time power exchange data, and the detection result is used for representing whether the real-time power exchange data is abnormal or not.

14. A server comprising a memory, a processor and a computer program stored on the memory and executable on the processor, characterized in that the processor implements the cloud management method of the power exchange station according to any of claims 1 to 12 when executing the computer program.

15. A computer readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements the cloud management method of a power exchange station according to any of claims 1 to 12.

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